Stella Novae: Pastand FutureDecades ASP Conference Series,Vol.490 P.A.Woudt andv. A.R.M.Ribeiro,eds. c 2014 AstronomicalSociety ofthe Pacific V496 Scuti: Detection ofco Emissionand DustShellin a ModeratelyFastFeII Nova AshishRaj, 1 N.M.Ashok, 1 D.P. K.Banerjee, 1 U.Munari, 2 P.Valisa, 2 ands.dallaporta 2 1 AstronomyandAstrophysicsDivision,PhysicalResearchLaboratory, NavrangpuraAhmedabad,380009 GujaratIndia 2 INAF AstronomicalObservatoryofPadova,36012Asiago(VI),Italy Abstract. Wepresentnear-infraredandopticalobservationsofmoderatelyfastFeIIclassNovaScuti2009(V496Sct)coveringvariousphases;pre-maximum,earlydecline and nebular, during the first 10 months after its discovery followed by limited observations up to 2011 April. In the initial phase the nova spectra show prominent P Cygni profiles and later all the lines are seen in emission. The notable feature of the near-ir spectra in the early decline phase is the rare presence of the first overtone bands of carbon monoxide (CO) in emission. The IR spectra show clear dust formation in the expanding ejecta at later phase about 150 days after the peak brightness. The presence of lines of elements with low ionization potentials like Na and Mg in the early IR spectra and the detection of CO bands in emission and the dust formation in V496 Sct represents a complete expected sequence in the dust formation in nova ejecta. The lightcurveshowsaslowrisetothemaximumandaslowdeclineindicatingaprolonged massloss. ThisiscorroboratedbythestrengtheningofPCygniprofilesduringthefirst 30days. Thebroadandsingleabsorptioncomponentsseeninmanylinesintheoptical spectra at the time of discovery are replaced by two sharper components in the spectra taken close to the optical maximum brightness. These sharp dips seen in the P Cygni absorption components of Feii and Hilines during the early decline phase show increasing outflow velocities. The onset of the nebular phase is evident from the optical spectrain2010march. Duringthenebularphase,severalemissionlinesdisplaysaddlelikeprofiles. Inthenebularstage,theobservedfluxesof[Oiii]andHβlinesareusedto estimate the electron number densities and the mass of the ejecta. The optical spectra show that the nova is evolved in the P fe A o spectral sequence. The absolute magnitude and the distance to the nova are estimated to be M V = 7.0±0.2 and d=2.9±0.3 kpc, respectively. 1. Introduction Nova Scuti 2009 (V496 Sct) was discovered by Nishimura on 2009 November 8.370 UT at V= 8.8 (Nakano et al. 2009) on two 10s unfiltered CCD images. The low resolution spectra obtained during the period 2009 November 9.73 UT to 10.08 UT which showed prominent Hα and Hβ emission lines with P Cygni components, along with the strong Feii multiplets and Oilines indicating that V496 Sct is an Feii class nova near maximum light (Munari et al. 2009a, Balam & Sarty 2009). The optical observations by Munari et al. (2009b) showed a post-discovery brightening for about 10 days before the onset of fading with maximum brightness V max = 7.07 around 2009 267
268 Raj etal. Figure 1. The model fits are shown as dashed lines to the observed first overtone CO bands in V496 Sct for 2009 December 5 and 7. The fits are made for a constant CO mass of 2 10 8 M on both the days while the temperature of the gas T CO is 4000Kand3600Krespectively. Thetimefromopticalmaximumaregivenforeach spectrum. November 18.716 UT. The IR observations by Rudy et al. (2009) on 2009 November 27.08 UT showed strong first overtone CO emission bands - an extremely short lived feature that is seen in only a few novae. They also predicted that dust formation in V496 Sct is almost certain. The first result by Raj, Ashok, & Banerjee (2009) showed thecontinuationofcoemissionduringtheperiod2009december3.55utto8.55ut. Subsequent observations by Russell et al. (2010) after V496 Sct came out of the solar conjunction showeddustformationon2010february10. TheIRandopticalobservationsfornovaV496SctaretakenfromMt. AbuIRObservatoryofPRLinIndia,atAsiagoObservatoryofUniversityofPadovaandINAFAstronomical Observatory of Padova and Schiaparelli Observatory in Italy, respectively. 2. Results 2.1. Theopticallightcurve: thepre-maximumrise,outburstluminosity,reddeningand distance Fromtheopticallightcurveweestimatet 2 tobe59±5d(rajetal.2012)whichmakes V496SctasoneofthemoderatelyfastFeIIclassofnovaeinrecentyears. V496Sctis one of the large amplitude novae observed in recent years with R 13.5 magnitudes
NovaScuti 2009 269 Figure 2. The low-resolution optical spectra of V496 Sct. The left panel shows the permittedphase (P fe )and right panel shows theauroral phase (A o ). (Guido & Sostero 2009). These observed values of the amplitude and t 2 for V496 Sct put it above the upper limit in the observed spread of the amplitude versus decline rate plot for classical novae presented by Warner (2008, their figure 2.3) which shows V = 8-11 for t 2 = 59 days. The height from the Galactic plane is estimated to be z= 89±3pc by using the value of the distance d=2.9±0.3 kpc (Raj et al. 2012) to the nova. The outburst luminosity of V496 Sct as calculated from M V is L O 5.1 10 4 L. A small plateau is also seen in the light curve between 128 and 215 days after the outburst. 2.2. Modeling andevolutionof thecoemission We adopt the model developed in the earlier work on V2615 Oph by Das, Banerjee, & Ashok(2009)to characterizetheco emission. The best fit model spectra to the observed data are obtained by varying the input parameters M CO,α, T CO (see Figure 1). The increase in M CO enhances the absolute level of the CO emission while the increase in T CO changes the relative intensities of different vibrational bands in addition to changing the absolute level of the emission. The CO emission is assumed to be optically thin. The Cilines at 2.2906 and 2.3130 µm and Nailines at 2.3348 and 2.3379µm are also likely to be present in the spectral region covered by the CO emission giving rise to some deviations between the best model fit and the observed spectra. The typical errors to the formal model fits are± 500 K. The model spectra with a reasonably similar range in mass of M CO = 1.5 2 10 8 M fit the observed spectra. The model calculations also show that theν=2-0 bandhead of 13 CO at 2.3130µm becomes discernibly prominent if the 12 C/ 13 C ratio is 1.5. As this spectral feature is not clearly detected in our observed spectra, we place alower limitof 1.5forthe 12 C/ 13 Cratio. 2.3. Evolution of theopticalspectraandestimationof ejectamass ThevariousphasesofthespectralevolutionofV496Scthavebeenidentifiedusingthe Tololoclassificationsystemfornovae(Williamsetal.1991;1994). Thepermittedlines of Feii were the strongest non-balmer lines in the pre-maximum as well as the early decline phase indicating P fe class for the nova. The nova had evolved to the auroral phase A o in 2010 March as the [Nii] 5755 auroral line was the strongest non-balmer line. We note the absence of [Fex] 6375 coronal emission line in the spectra taken as
270 Raj etal. Figure 3. The two panels show the case B analysis for 2009 December 6 for two different temperatures. The abscissa is the upper level number of the Brackett series line transition. The line intensities are relative to that of Br 12. The Case B model predictions for the line strengths are also shown for a temperature of T=10 4 K and electron densities ofn e = 10 12 cm 3 (dashed line) and 10 8 cm 3 (solidline). lateas2011april19(seefigure2). Thustheopticalspectrashowthatthenovaevolved in the P fe A o spectral sequence. We have also tried to estimate the ejecta mass by using recombination line analysis of Hilines for 2009 December 6 (Figure 3). However, we find that the strengths of these lines, relative to each other, deviate considerably (specially for Brγ, Figure 3) from Case B values for 2009 December 6 indicating that the lines are optically thick. Hence we are unable to estimate the ejecta mass from recombination analysis. From the optical spectra, we estimated the mass of oxygen M OI intherange1.18 10 5 2.28 10 6 M. Themassofhydrogenm(H)intheejecta is (6.3±0.2) 10 5 M. We obtain M dust = 1-5 10 10 M for 2010 April 30 from the best fit value T dust = 1500±200 K (withχ 2 minimization) for d=2.9 kpc. Hence the gas to dust ratio is found to be M gas /M dust 1.3 6.3 10 5 indicating that a small amount of dust was formed in V496 Sct comparable to 3 10 5 observed in the case of V2362Cyg bymunarietal.(2008). Acknowledgments. TheresearchworkatPhysicalResearchLaboratoryisfunded bythedepartmentofspace,governmentofindia. WewouldliketothankA.Frigo,V. Luppi,L.Buzzi,A. Milani,G. Cherini, A.Maitan,L.Baldinelli (ANSCollaboration). References Balam, D.,&Sarty, G. 2009, IAUCirc., 9093 Das, R. K.,Banerjee, D.P. K.,&Ashok, N.M. 2009, MNRAS, 398, 375 Munari, U., Siviero, A.,Buzzi, L., & Valisa, P. 2009a, IAUCirc., 9093 Munari, U., Siviero, A.,Henden, A., et al.2008, A&A, 492, 145 Munari, U., Siviero, A.,Valisa, P., Dallaporta, S.,&Baldinelli, L. 2009b, Central Bureau ElectronicTelegrams, 2034 Nakano, S., Nishimura, H.,Guido, E., Sostero, G., & Kazarovets, E. V. 2009, IAU Circ.,9093 Raj, A., Ashok, N. M.,&Banerjee, D. P. K.2009, Central Bureau Electronic Telegrams, 2069
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